A qubit assembly includes a first superconducting loop comprising a first Josephson junction and a second Josephson junction, a second superconducting loop comprising the second Josephson junction and a third Josephson junction, and a third superconducting loop comprising the third Josephson junction and a fourth Josephson junction. A flux source is configured to provide a control flux to the second superconducting loop, such that the effective commutation relations between a first quantum operator corresponding to current in the first superconducting loop and a second quantum operator corresponding to current in the third superconducting loop can be changed by changing a magnitude of the control flux provided to the second superconducting loop by the flux source.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A qubit assembly comprising: a first superconducting loop comprising a first Josephson junction and a second Josephson junction; a second superconducting loop comprising the second Josephson junction and a third Josephson junction; a third superconducting loop comprising the third Josephson junction and a fourth Josephson junction; and a flux source configured to provide a magnetic control flux to the second superconducting loop, such that the effective commutation relations between a first quantum operator corresponding to current in the first superconducting loop and a second quantum operator corresponding to current in the third superconducting loop can be changed by changing a magnitude of the magnetic control flux provided to the second superconducting loop by the flux source.
2. The qubit assembly of claim 1 , wherein the first quantum operator represents a selected X-axis for the qubit assembly and the second quantum operator can be configured to represent an arbitrary axis within a plane of the Bloch sphere by changing a magnitude of the magnetic control flux provided to the second superconducting loop.
3. The qubit assembly of claim 2 , wherein a quantum operator corresponding to voltage on the superconducting island adjoining the loops represents a third axis within the Bloch sphere perpendicular to each of the X-axis and the arbitrary axis.
4. The qubit assembly of claim 1 , wherein the magnetic control flux is a first magnetic control flux, and the qubit assembly further comprises fourth and fifth superconducting loops, with the fourth loop comprising the first Josephson junction and a fifth Josephson junction and the fifth loop comprising the fifth Josephson junction and a sixth Josephson junction, the flux source being configured to provide a second magnetic control flux to the fourth superconducting loop, such that the effective commutation relations between the first quantum operator and a third quantum operator corresponding to current in the fifth superconducting loop can be changed by changing a magnitude of the second magnetic control flux.
5. The qubit assembly of claim 1 , wherein the first superconducting loop comprises a first path to ground, interrupted by the first Josephson junction, and a second path to ground, interrupted by the second Josephson junction, the second superconducting loop comprises the second path to ground and a third path to ground, interrupted by the third Josephson junction, and the third superconducting loop comprises the third path to ground and a fourth path to ground, interrupted by the fourth Josephson junction.
6. The qubit assembly of claim 1 , wherein at least one of the first Josephson junction, the second Josephson junction, the third Josephson junction, and the fourth Josephson junction is a compound Josephson junction.
7. The qubit assembly of claim 1 , further comprising a readout resonator coupled to the third superconducting loop and configured to measure a state of the second quantum operator.
8. A quantum system comprising: the qubit assembly of claim 1 , wherein the flux source is a first flux source and the magnetic control flux is a first magnetic control flux; and a second qubit assembly comprising: a fourth superconducting loop comprising a fifth Josephson junction and a sixth Josephson junction; a fifth superconducting loop comprising the sixth Josephson junction and a seventh Josephson junction; a sixth superconducting loop comprising the seventh Josephson junction and a eighth Josephson junction; and a second flux source configured to provide a second magnetic control flux to the fifth superconducting loop, such that the effective commutation relations between a third quantum operator corresponding to current in one of the fourth superconducting loop and a fourth quantum operator corresponding to current in the sixth superconducting loop can be changed by changing a magnitude of the second magnetic control flux; and a coupling assembly configured to couple the third superconducting loop to the sixth superconducting loop.
9. The quantum system of claim 8 , wherein the coupling assembly is a tunable coupler comprising a compound Josephson junction.
10. A method comprising: coupling a first superconducting loop, associated with a first qubit and having an associated first quantum operator, to a second superconducting loop, associated with a second qubit and having an associated second quantum operator; providing a first control flux to the first qubit to tune the first quantum operator to represent an axis of the Bloch sphere; and providing a second control flux to the second qubit to tune the second quantum operator to represent the axis of the Bloch sphere, such that the first qubit and the second qubit are coupled along the axis of the Bloch sphere associated with the first and second quantum operators.
11. The method of claim 10 , wherein providing the first control flux to the first qubit comprises providing the first control flux to a third superconducting loop that shares at least one Josephson junction with the first superconducting loop.
12. The method of claim 11 , wherein a the axis of the Bloch sphere represented by the first current operator varies with a value, ϕ, for the first control flux in a manner proportional to COS ( 2 πϕ ϕ 0 ) σ x + sin ( 2 πϕ ϕ 0 ) σ y .
13. The method of claim 10 , coupling the first superconducting loop to the second superconducting loop comprises providing a third control flux to a tunable coupler assembly positioned between the first superconducting loop and the second superconducting loop.
14. A system comprising: a first qubit assembly comprising: a first superconducting loop comprising a first Josephson junction and a second Josephson junction; a second superconducting loop comprising the second Josephson junction and a third Josephson junction; a third superconducting loop comprising the third Josephson junction and a fourth Josephson junction; a first flux source configured to provide a first magnetic control flux to the second superconducting loop, such that the effective commutation relations between a first quantum operator corresponding to current in the first superconducting loop and a second quantum operator corresponding to current in the third superconducting loop can be changed by changing a magnitude of the first magnetic control flux provided to the second superconducting loop by the first flux source; a second qubit assembly comprising: a fourth superconducting loop comprising a fifth Josephson junction and a sixth Josephson junction; a fifth superconducting loop comprising the sixth Josephson junction and a seventh Josephson junction; a sixth superconducting loop comprising the seventh Josephson junction and a eighth Josephson junction; and a second flux source configured to provide a second magnetic control flux to the fifth superconducting loop, such that the effective commutation relations between a third quantum operator corresponding to current in one of the fourth superconducting loop and a fourth quantum operator corresponding to current in the sixth superconducting loop can be changed by changing a magnitude of the second magnetic control flux; and a coupling assembly configured to couple the third superconducting loop to the sixth superconducting loop.
15. The system of claim 14 , wherein the coupling assembly is a first coupling assembly, the system further comprising a third qubit assembly coupled to the first qubit assembly via a second coupling assembly such that an alignment of respective voltage operators associated with the first qubit assembly and the third qubit assembly is energetically favorable.
16. The system of claim 14 , wherein the coupling assembly is a first coupling assembly, the system further comprising: a third qubit assembly comprising: a seventh superconducting loop comprising a ninth Josephson junction and a tenth Josephson junction; a eighth superconducting loop comprising the tenth Josephson junction and a eleventh Josephson junction; a ninth superconducting loop comprising the eleventh Josephson junction and a twelfth Josephson junction; and a third flux source configured to provide a third magnetic control flux to the eighth superconducting loop, such that the effective commutation relations between a fifth quantum operator corresponding to current in one of the seventh superconducting loop and a sixth quantum operator corresponding to current in the ninth superconducting loop can be changed by changing a magnitude of the third magnetic control flux; and a second coupling assembly configured to couple the first superconducting loop to the seventh superconducting loop.
17. The system of claim 16 , the system further comprising a fourth qubit assembly coupled to the first qubit assembly via a third coupling assembly such that an alignment of respective voltage operators associated with the first qubit assembly and the fourth qubit assembly is energetically favorable.
18. The system of claim 14 , wherein the coupling assembly is a tunable coupler comprising a compound Josephson junction.
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June 19, 2019
July 19, 2022
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